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Kalman Filter

In this repository, we have implemented a Kalman filter to track the motion of a drone flying through open space. The drone's position is monitored by a Qualisys motion capture system, which uses infrared cameras to track spherical retroreflective markers on the drone. The system can capture the drone's motion at a rate of over 100 Hz.

System Modelling

The system is modeled using a state vector consisting of the drone’s position and velocity. Let p = [x, y, z]^T denote the position vector, and = [ẋ, ẏ, ż]^T denote the velocity vector. With this representation, the state vector becomes:

x = [x, y, z, ẋ, ẏ, ż]^T

The noise is assumed to be zero. Control input vector u(t) is expressed as:

u(t) = m * 𝑝̈

In this model, we have the input vectors at each timestamp, u. Thus, we estimate the acceleration from u because of our known model. The Process Model is when we rely on a model. Then we correct our estimate using our sensors or the Measurement model. This is a case of odometry based on physical tracking of the drone.

Process Model

The state transition model is given by the standard Kalman filter equation:

ẋ = A * x + B * u

The state transition matrix A becomes:

A = [ 0  0  0  1  0  0
      0  0  0  0  1  0
      0  0  0  0  0  1
      0  0  0  0  0  0
      0  0  0  0  0  0
      0  0  0  0  0  0 ]

The input matrix B becomes:

B = [ 0   0   0
      0   0   0
      0   0   0
     1/m  0   0
      0  1/m  0
      0   0  1/m ]

Continuous to Discrete

To work with real data, we need to discretize the continuous model. We use Euler's one-step method to discretize:

x(t + Δt) = x(t) + Δt * (A * x(t) + B * u(t) + N(t))

The state transition matrix F is given by:

F = I + Δt * A = [ 1   0   0  Δt  0   0
                   0   1   0   0  Δt  0
                   0   0   1   0   0  Δt
                   0   0   0   1   0   0
                   0   0   0   0   1   0
                   0   0   0   0   0   1 ]

The input matrix G is given by:

G = Δt * B = [  0    0    0
                0    0    0
                0    0    0
             Δt/m   0    0
               0  Δt/m   0
               0    0  Δt/m ]

Measurement Model

y = C * x + V(noise)

Since the sensor here is the IMU, we have a simple observation model.

  • If the measurement is position (z = p):
C_position = [ 1  0  0  0  0  0
               0  1  0  0  0  0
               0  0  1  0  0  0 ]
  • If the measurement is velocity (z = ṗ):
C_velocity = [ 0  0  0  1  0  0
               0  0  0  0  1  0
               0  0  0  0  0  1 ]

Since the Kalman filter is a discrete filter, we discretize the system using the one-step Euler integration method. The first-order Markov assumption makes the Kalman filter system model a first-order differential equation:

ẋ = A * x + B * u + E * N(0, Q)

Kalman Filter

1. P Matrix (Error Covariance Matrix)

  • Purpose: Represents the covariance of the error in the estimated state.
  • Role: Tracks the uncertainty of the state estimate.
  • Dimension: If the state vector x has n dimensions, P is an n × n matrix.
  • Key Point: Diagonal elements represent the variance, and off-diagonal elements represent correlations.

2. Q Matrix (Process Noise Covariance Matrix)

  • Purpose: Models the covariance of process noise.
  • Role: Represents uncertainty in system dynamics. Higher values in Q indicate more uncertainty in the model.
  • Dimension: n × n matrix.
  • Key Point: If the process model is perfect, Q would be zero.

3. R Matrix (Measurement Noise Covariance Matrix)

  • Purpose: Describes the covariance of noise in sensor measurements.
  • Role: Accounts for the noise in sensor data. Higher values in R mean the filter relies less on measurements.
  • Dimension: m × m matrix (where m is the size of the measurement vector).
  • Key Point: Represents confidence in sensor readings.

4. K Matrix (Kalman Gain Matrix)

  • Purpose: Balances the trade-off between model predictions and sensor measurements.
  • Role: Determines how much of the correction step is influenced by sensor measurements.
  • Key Point: Used to update the state estimate.

The following equations define the Kalman Filter process:

μ̅_t = F * μ_(t-1) + G * u_t
Σ̅_t = F * Σ_(t-1) * F^T + V * Q * V^T
K = Σ̅_t * C^T * (C * Σ̅_t * C^T + R)^(-1)
μ_t = μ̅_t + K * (z_t - C * μ̅_t)
Σ_t = (I - K * C) * Σ̅_t

The Q matrix is initialized as:

Q = σ^2 * (G * G^T)

The P matrix is initialized with a large value since the initial state is unknown.

The R matrix is chosen based on the type of measurement:

R = σ^2 * I

where σ ranges from 0.1 to 1.0 in this case.

Results

Drone Tracking by Kalman Filter

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